Machine learning methods and systems for variety profile index crop characterization

ABSTRACT

A computing system includes a processor and a non-transitory, computer-readable medium including instructions that, when executed by the processor, causes the computing system to receive a machine data set; process the machine data set using a trained machine-learned model to generate predicted variety profile index values, and transmit the variety profile index values to a client computing device. A computer-implemented method includes receiving a machine data set; processing the machine data set using a trained machine-learned model to generate predicted variety profile index values, and transmitting the variety profile index values to a client computing device. A non-transitory computer-readable medium includes instructions stored thereon that, when executed by one or more processors, cause a computer to receive a machine data set; process the machine data set using a trained machine-learned model to generate predicted variety profile index values, and transmit the variety profile index values to a client computing device.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.17/694,661, entitled MACHINE LEARNING METHODS AND SYSTEMS FOR VARIETYPROFILE INDEX CROP CHARACTERIZATION, filed on Mar. 14, 2022, whichclaims the benefit of U.S. Provisional Application 63/174,386, filedApr. 13, 2021, and entitled MACHINE LEARNING METHODS AND SYSTEMS FORVARIETY PROFILE INDEX CROP CHARACTERIZATION, the entire contents ofwhich are incorporated herein by reference in its entirety.

TECHNICAL FIELD

The present disclosure is generally directed to methods and systems forcharacterizing soybeans, and more specifically, for generating fieldmanagement recommendations based on one or more determined soybeancharacteristics within a field and/or sub-field.

BACKGROUND

Growers and trusted advisors struggle to gain an understanding of thegrowing behavior of soybeans in agricultural fields. Conventionally usedsoybean characteristics, such as tall, bushy, etc., are subjective anddo not lend themselves to analysis when trying to understand whichsoybean varieties will grow well in which fields and under which growingconditions. Thus, growers and trusted advisors are often unsure whichsoybean variety to plant, a consideration only complicated by thevariability among different agricultural fields.

Further, conventional techniques for characterizing soybeans may requireintensive manual labor of many individuals (e.g., one hundred or more)for a single field. Such techniques may include extensive delays of timerelated to crop sample preparation (e.g., manual threshing, drying,weighing, etc.) in addition to machinery for collection, and storagefacilities for storage.

Still further, the subjective nature of recommendations regarding fieldvarieties and planting is conventionally based on grower intuition,anecdote, and other unreliable and unreproducible information. Fieldmanagers, trusted advisors and seed companies are unable to quantifyperformance of varieties, and thus, are unable to compare performancewhen making recommendations.

BRIEF SUMMARY

In one aspect, a computing system for characterizing soybean plantsusing machine learning, the computing system includes one or moreprocessors; and one or more non-transitory, computer-readable mediaincluding instructions that, when executed by the one or moreprocessors, cause the computing system to: (i) receive a machine dataset corresponding to an agricultural field; (ii) process the machinedata set with a trained machine-learned model to generate one or morepredicted variety profile index values, the trained machine-learnedmodel trained using labeled data including a ratio of at least onemeasured branch bean weight to at least one measured stem bean weight;and (iii) transmit, via an electronic network, the one or more predictedvariety profile index values to a client computing device.

In another aspect, a computer-implemented method for training a machinelearning model to characterize soybean plants includes (i) receiving amachine data set corresponding to an agricultural field; (ii) processingthe machine data set with a trained machine-learned model to generateone or more predicted variety profile index values, the trainedmachine-learned model trained using labeled data including a ratio of atleast one measured branch bean weight to at least one measured stem beanweight; and (iii) transmitting, via an electronic network, the one ormore predicted variety profile index values to a client computingdevice.

In yet another aspect, a non-transitory computer-readable mediumincludes instructions stored thereon that, when executed by one or moreprocessors, cause a computer to (i) receive a machine data setcorresponding to an agricultural field; (ii) process the machine dataset with a trained machine-learned model to generate one or morepredicted variety profile index values, the trained machine-learnedmodel trained using labeled data including a ratio of at least onemeasured branch bean weight to at least one measured stem bean weight;and (iii) transmit, via an electronic network, the one or more predictedvariety profile index values to a client computing device.

BRIEF DESCRIPTION OF THE FIGURES

The figures described below depict various aspects of the system andmethods disclosed therein. It should be understood that each figuredepicts one embodiment of a particular aspect of the disclosed systemand methods, and that each of the figures is intended to accord with apossible embodiment thereof. Further, wherever possible, the followingdescription refers to the reference numerals included in the followingfigures, in which features depicted in multiple figures are designatedwith consistent reference numerals.

FIG. 1 depicts an example computing environment, according to anembodiment.

FIG. 2 depicts an example soybean plant.

FIG. 3 is a block diagram illustrating an example implementation of thevariety profile index determining module of FIG. 1 , according to anembodiment.

FIG. 4 is a flow diagram of an example computer-implemented method fortraining a machine-learned model for predicting VPI values within anagricultural field, according to an embodiment.

FIG. 5 is a flow diagram of an example computer-implemented method forimproving agricultural treatment application within an agriculturalfield, according to an embodiment.

FIG. 6A depicts an example chart for visualizing yield performance amongproducts having differing variety profile indices, according to anembodiment.

FIG. 6B depicts an example chart for visualizing average variety profileindices across products among different fields, according to anembodiment.

FIG. 6C depicts an example chart for visualizing soil wetness index datacompared to average yield among different products, according to anembodiment.

FIG. 6D depicts an example chart for visualizing average variety profileindex for a plurality of agricultural varieties, according to anembodiment.

FIG. 6E depicts an example chart for visualizing yields according toplant population among a plurality of agricultural varieties, accordingto an embodiment.

FIG. 7 depicts an exemplary multi-genetics prescription map, accordingto one embodiment and scenario.

The figures depict preferred embodiments for purposes of illustrationonly. One of ordinary skill in the art will readily recognize from thefollowing discussion that alternative embodiments of the systems andmethods illustrated herein may be employed without departing from theprinciples of the invention described herein.

DETAILED DESCRIPTION Overview

The present disclosure is generally directed to methods and systems forcharacterizing soybeans, and more specifically, for generating fieldmanagement recommendations based on one or more determined soybeancharacteristics within a field and/or sub-field.

Disclosed techniques advantageously improve the ability of individualsand organizations (e.g., a grower, a trusted advisor, a seed company,etc.) that own and/or manage agricultural fields to objectively measuresoybean plant growth in those agricultural fields, both at the field andsub-field level. In particular, the present techniques may determinegrowth structures of soybean plants to objectively analyze and informmanagement decisions and/or to assist in product placement.

FIG. 2 is a diagram of an example soybean plant 200 that may be one ofthe soybean plants 101 of FIG. 1 . The soybean plant 200 of FIG. 2 has aroot structure 202, a main stem or stalk 204, and two branches 206 and208. Other soybean plants may have a different number (including zero)branches. The number and extent of the branches 206 (if any) determinethe bushiness of the soybean plant 200. That is, the more branches andthe larger the branches, the larger and more bushy the soybean plant.Pods of beans (two of which are designated at reference numerals 210Aand 210B) will grow on the stalk 204, and pods of beans (two of whichare designated at reference numerals 212A and 212B) will grow on thebranches 206, 208.

A disclosed example objective characterization of the bushiness of asoybean plant is a variety profile index (VPI) value. A VPI value for asoybean plant may be computed as a ratio of branch bean weight and stembean weight, where branch bean weight is the total weight of the beansassociated with the branches of a soybean plant, and stem bean weight isthe total weight of the beans associated with the stem of the soybeanplant. Branch bean weight and stem bean weight may be measured indifferent ways, in embodiments. For example, a bean may be measured asassociated with a stem or a respective branch when the pod in which itdeveloped is attached to the stem or the respective branch. The VPIvalue for a soybean plant can be expressed mathematically as:VPI=total weight of beans associated with branches/total weight of beansassociated with stem.

In some embodiments, the present techniques compute a VPI value for asoybean plant via a process that includes 1) threshing the plant toseparate the beans associated with the stem from the beans associatedwith the branches; 2) drying the stem and branch beans (if not alreadydried); 3) weighing the beans; and 4) computing the ratio of branchbeans to stem beans. In some embodiments, this process may be a manualprocess and/or an automated process (e.g., a process that utilizes oneor more farming implements). In some embodiments, the present techniquesmay include computing one or more VPI values using respective subsets ofthe beans from the soybean plant. For example, the present techniquesmay include computing a first VPI value of beans associated with a lowerportion of the soybean plant (e.g., the beans from the roots of thesoybean plant to the fifteenth above-ground node of the soybean plant).Such lower beans may be associated with earlier season growth. In someexamples, multiple VPI values can be measured across a field or fieldsubdivision (e.g., a hexagrid, as discussed below) and averaged.

The present techniques may include analyzing one or more computed VPIvalues to identify one or more respective soybean varieties (e.g.,varieties having higher VPI values) with respect to one or more field orsub-field environments. For example, the present techniques may analyzeVPI values of a field to determine one or more soybean varieties likelyto develop branches in response to a higher yield environment. In someembodiments, the present techniques may analyze computed VPI values todetermine management strategies (e.g., to determine a planting date, aplant population, a fungicide timing, an insecticide timing, etc.).

The present techniques include methods and systems for collectingmachine data and for determining soybean characteristics (e.g., VPIvalues) within one or more agricultural fields by analyzing the machinedata. In some embodiments, the soybean characteristics may be encoded inspatial data files encoded in a suitable file format, such as acommercial or open source shapefile, a GeoJSON format, a GeographyMarkup Language (GML) file, etc. Such spatial data files may include oneor more layers (i.e., map layers, wherein each layer represents anagricultural characteristic (e.g., elevation, VPI values, etc.)). Theindividual layer(s) and/or files may be shared between multiplecomputing devices of an agricultural company, provided or sold tocustomers, stored in a database, etc.

Exemplary Computing Environment

FIG. 1 depicts an exemplary computing environment 100 in which thetechniques disclosed herein may be implemented, according toembodiments.

The environment 100 includes a client computing device 102, an implement104, a remote computing device 106, and a network 108. Some embodimentsmay include a plurality of client computing devices.

The client computing device 102 may be an individual server, a group(e.g., cluster) of multiple servers, or another suitable type ofcomputing device or system (e.g., a collection of computing resources).For example, the client computing device 102 may be a mobile computingdevice (e.g., a server, a mobile computing device, a smart phone, atablet, a laptop, a wearable device, etc.). In some embodiments theclient computing device 102 may be a personal portable device of a user.In some embodiments the client computing device 102 may be temporarilyor permanently coupled with the implement 104. The client computingdevice 102 may be the property of a customer, an agricultural analytics(or “agrilytics”) company, an implement manufacturer, etc.

The client computing device 102 includes a processor 110, a memory 112and a network interface controller (NIC) 114. The processor 110 mayinclude any suitable number of processors and/or processor types, suchas CPUs, one or more graphics processing units (GPUs), digital signalprocessor(s) (DSPs), etc. Generally, the processor 110 is configured toexecute software instructions stored in a memory 112. The memory 112 mayinclude one or more persistent memories (e.g., a hard drive/solid statememory) and stores one or more set of computer executableinstructions/modules, including a data collection module 116, a mobileapplication module 118, and an implement control module 120, asdescribed in more detail below. More or fewer modules may be included insome embodiments. The NIC 114 may include any suitable network interfacecontroller(s), such as wired/wireless controllers (e.g., Ethernetcontrollers), and facilitate bidirectional/multiplexed networking overthe network 108 between the client computing device 102 and othercomponents of the environment 100 (e.g., another client computing device102, the implement 104, the remote computing device 106, etc.). In someexamples, the NIC 114 is external and communicatively coupled to theclient computing device 102 as a peripheral device.

The one or more modules stored in the memory 112 may include respectivesets of computer-executable instructions implementing specificfunctionality. For example, in an embodiment, the data collection module116 includes a set of computer-executable instructions for collecting amachine data set from an implement (e.g., the implement 104). The datacollection module 116 may include instructions for collecting anabove-ground and/or below-ground soil sample.

The machine data collection module 116 may include a respective set ofinstructions for retrieving/receiving data from a plurality of differentimplements. For example, a first set of instructions may be forretrieving/receiving machine data from a first tractor manufacturer'sproducts, while a second set of instructions is for retrieving/receivingmachine data from a second tractor manufacturer's products. In anotherembodiment, the first and second set of instructions may be for,respectively, receiving/retrieving data from tillage equipment and aharvester. Of course, some libraries of instructions may be provided bythe manufacturers of various implements and/or attachments, and may beloaded into the memory 112 and used by the data collection module 116.The data collection module 116 may retrieve/receive machine data from aseparate hardware device (e.g., a client computing device 102 that ispart of the implement 104) or directly from one or more of the sensorsof the implement 104 and/or one or more of the attachments 130 coupledto the implement 104, if any.

The machine data may include any information generated by the clientcomputing device 102, the implement 104 and/or the attachments 130. Insome cases, the machine data may be retrieved/received via the remotecomputing device 106 (e.g., from a third-party cloud storage platform).For example, the machine data may include values generated via a soilslaboratory or by analyzing a soil sample using a soil analysisattachment 130. The machine data may include sensor measurements ofengine load data, fuel burn data, draft, fuel consumption, wheelslippage, etc. The machine data may include one or more time series,such that one or more measured values are represented in a single dataset at a common interval (e.g., one-second). For example, the machinedata may include a first time series of draft at a one-second interval,a second time series of wheel slippage, etc.

The machine data may be location-aware. For example, the clientcomputing device 102 may add location metadata to the machine data, suchthat the machine data reflects an absolute and/or relative geographicposition (i.e., location, coordinate, offset, heading, etc.) of theclient computing device 102, the implement 104, and/or the attachments130 within the agricultural field at the precise moment that the clientcomputing device 102 captures the machine data. It will also beappreciated by those of ordinary skill in the art that some sensorsand/or agricultural equipment may generate machine data that is receivedby the client computing device 102 already includes location metadataadded by the sensors and/or agricultural equipment. In an embodimentwherein the machine data comprises a time series, each value of the timeseries may include a respective geographic metadata entry. It will befurther appreciated by those of ordinary skill in the art that when themachine data is received from a historical archive, the machine data mayinclude historical location data (e.g., the GPS coordinatescorresponding to the location from which the historical machine data wascaptured).

The machine data collection module 116 may receive, access and/orretrieve the machine data via an API through a direct hardware interface(e.g., via one or more wires) and/or via a network interface (e.g., viathe network 108). The data collection module 116 may collect (e.g., pullthe machine data from a data source and/or receive machine data pushedby a data source) at a predetermined time interval. The time intervalmay be of any suitable duration (e.g., once per second, once or twiceper minute, every 10 minutes, etc.). The time interval may be short, insome embodiments (e.g., once every 10 milliseconds). The data collectionmodule 116 may include instructions for modifying and/or storing themachine data. For example, the data collection module 116 may parse theraw machine data into a data structure. The data collection module 116may write the raw machine data onto a disk (e.g., a hard drive in thememory 112).

In some embodiments, the machine data collection module 116 may transferthe raw machine data, or modified machine data, to a remote computingsystem/device, such as the remote computing device 106. The transfermay, in some embodiments, take the form of an SQL insert command. Ineffect, the data collection module 116 performs the function ofreceiving, processing, storing, and/or transmitting the machine data.The data collection module 116 may receive (e.g., from a soil probeattachment) soil sample data corresponding to one or more points withinthe machine data.

The mobile application module 118 may include computer-executableinstructions that display one or more graphical user interfaces (GUIs)on one or more output devices 126 and/or receive user input via one ormore input devices 124. For example, the mobile application module 118may correspond to a mobile computing application (e.g., an Android,iPhone, or other) computing application of an agrilytics company. Themobile computing application may be a specialized applicationcorresponding to the type of computing device embodied by the clientcomputing device 102. For example, in embodiments where the clientcomputing device 102 is a mobile phone, the mobile application module118 may correspond to a mobile application downloaded for the mobilephone. When the client computing device 102 is a tablet, the mobileapplication module 118 may correspond to an application withtablet-specific features. Exemplary GUIs that may be displayed by themobile application module 118, and with which the user may interact, arediscussed below.

The mobile application module 118 may include instructions forreceiving/retrieving mobile application data from the remote computingdevice 106. In particular, the mobile application module 118 may includeinstructions for transmitting user-provided login credentials, receivingan indication of successful/unsuccessful authentication, and otherfunctions related to the user's operation of the mobile application. Themobile application module 118 may include instructions forreceiving/accessing/retrieving, rendering, and displaying visual maps ina GUI. Specifically, the application module 118 may includecomputer-executable instructions for displaying one or more map layersin the output device(s) 126 of the client computing device 102. The maplayers may depict, for example, one or more clay types within anagricultural field.

The implement control module 120 includes computer-executableinstructions for controlling the operation of an implement (e.g., theimplement 104) and/or the attachments 130. The implement control module120 may control the implement 104 while the implement 104 and/orattachments 130 are in motion (e.g., while the implement 104 and/orattachments 130 are being used in a farming capacity). For example, theimplement control module 120 may include an instruction that, whenexecuted by the processor 110 of the client computing device 102, causesthe implement 104 to accelerate or decelerate, collect a soil sampleusing a soil probe, or change varieties on a planter.

In some embodiments, the implement control module 120 may cause one ofthe attachments 130 to raise or lower the disc arm of tillage equipment,or to apply more or less downward or upward pressure on the ground. Insome embodiments, the implement control module 120 may control theattachments 130 in response to a predicted VPI value corresponding tothe agricultural field where the implement 104 is positioned.Practically, the implement control module 120 has all of the control ofthe implement 104 and/or attachments 130 as does the human operator.

The implement control module 120 may include a respective set ofinstructions for controlling a plurality of implements. For example, afirst set of instructions may be for controlling an implement of a firsttractor manufacturer, while a second set of instructions is forcontrolling an implement of a second tractor manufacturer. In anotherembodiment, the first and second set of instructions may be for,respectively, controlling a tiller and a harvester. Of course, manyconfigurations and uses are envisioned beyond those provided by way ofexample.

In some embodiments, the implement control module 120 may includecomputer-executable instructions for executing one or more agriculturalprescriptions with respect to a field. For example, the control module120 may execute an agricultural prescription that specifies, for a givenagricultural field, a varying application rate of a chemical (e.g., afertilizer, an herbicide, a pesticide, etc.) or a seed to apply atvarious points along the path based on the clay characteristics of thefield. The control module 120 may analyze the current location of theimplement 104 and/or the attachments 130 in real-time (i.e., as thecontrol module 120 executes the agricultural prescription).

In some embodiments, one or more components of the computing device 102may be embodied by one or more virtual instances (e.g., a cloud-basedvirtualization service). In such cases, one or more client computingdevice 102 may be included in a remote data center (e.g., a cloudcomputing environment, a public cloud, a private cloud, etc.). Forexample, a remote data storage module (not depicted) may remotely storedata received/retrieved by the computing device 102. The clientcomputing device 102 may be configured to communicate bidirectionallyvia the network 108 with the implement 104 and/or an attachment 130 thatmay be coupled to the implement 104. The implement 104 and/or theattachments 130 may be configured for bidirectional communication withthe client computing device 102 via the network 108.

The client computing device 102 may receive/retrieve data (e.g., machinedata) from the implement 104, and/or the client computing device 102 maytransmit data (e.g., instructions) to the implement 104. The clientcomputing device 102 may receive/retrieve data (e.g., machine data) fromthe attachments 130, and/or may transmit data (e.g., instructions) tothe attachments 130. The implement 104 and the attachments 130 will nowbe described in further detail.

The implement 104 may be any suitable powered or unpoweredequipment/machine or machinery, including without limitation: a tractor,a combine, a cultivator, a cultipacker, a plow, a harrow, a stripper, atiller, a planter, a baler, a sprayer, an irrigator, a sorter, aharvester, etc. The implement 104 may include one or more sensors (notdepicted) including one or more soil probe and the implement 104 may becoupled to one or more attachments 130. For example, the implement 104may include one or more sensors for measuring respective implementvalues of engine load data, fuel burn data, draft sensing, fuelconsumption, wheel slippage, etc. Many embodiments including more orfewer sensors measuring more or fewer implement values are envisioned.The implement 104 may be a gas/diesel, electric, or hybrid vehicleoperated by a human operator and/or autonomously (e.g., as anautonomous/driverless agricultural vehicle).

The attachments 130 may be any suitable powered or unpoweredequipment/machinery permanently or temporarily affixed/attached to theimplement 104 by, for example, a hitch, yoke or other suitablemechanism. The attachments 130 may include any of the types of equipmentthat the implement 104 may comprise (e.g., field cultivator, disc,planter). The attachments 130 may include one or more sensors (notdepicted) that may differ in number and/or type according to therespective type of the attachments 130 and the particularembodiment/scenario. For example, a tiller attachment 130 may includeone or more soil coring probes. It should be appreciated that manyattachments 130 sensor configurations are envisioned. For example, theattachments 130 may include one or more cameras. The attachments 130 maybe connected to the implement 104 via wires or wirelessly, for bothcontrol and communications. For example, attachments 130 may be coupledto the client computing device 102 of the implement 104 via a wiredand/or wireless interface for data transmission (e.g., IEEE 802.11,WiFi, Bluetooth®, universal serial bus (USB), etc.) and main/auxiliarycontrol (e.g., 7-pin, 4-pin, etc.). The client computing device 102 maycommunicate bidirectionally (i.e., transmit data to, and/or receive datafrom) with the remote computing device 106 via the network 108.

The client computing device 102 includes the input device(s) 124 andoutput device(s) 126. The input device(s) 124 may include any suitabledevice or devices for receiving input, such as one or more microphone,one or more camera, a hardware keyboard, a hardware mouse, a capacitivetouch screen, etc. The output device(s) 126 may include any suitabledevice for conveying output, such as a hardware speaker, a computermonitor, a touch screen, etc. In some cases, the input device(s) 124 andthe output device(s) 126 may be integrated into a single device, such asa touch screen device that accepts user input and displays output. Theclient computing device 102 may be associated with (e.g., leased, owned,and/or operated by) an agrilytics company.

The network 108 may be a single communication network, or may includemultiple communication networks of one or more types (e.g., one or morewired and/or wireless local area networks (LANs), and/or one or morewired and/or wireless wide area networks (WANs) such as the Internet).The network 108 may enable bidirectional communication between theclient computing device 102 and the remote computing device 106, orbetween multiple client computing devices 102, for example.

The remote computing device 106 includes a processor 140, a memory 142,and a NIC 144. The processor 140 may include any suitable number ofprocessors and/or processor types, such as CPUs and one or more graphicsprocessing units (GPUs) or digital signal processors (DSPs). Generally,the processor 140 is configured to execute software instructions storedin the memory 142. The memory 142 may include one or more persistentmemories (e.g., a hard drive/solid state memory) and stores one or moreset of computer executable instructions/modules, as discussed below. Forexample, the remote computing device 106 may include a data processingmodule 150, a topographic module 152, a VPI determining module 154 and aprescription module 156. The NIC 144 may include any suitable networkinterface controller(s), such as wired/wireless controllers (e.g.,Ethernet controllers), and facilitate bidirectional/multiplexednetworking over the network 108 between the remote computing device 106and other components of the environment 100 (e.g., another remotecomputing device 106, the client computing device 102, etc.).

The one or more modules stored in the memory 142 may include respectivesets of computer-executable instructions implementing specificfunctionality. For example, in an embodiment, the data processing module150 includes computer-executable instructions for receiving/retrievingdata from the client computing device 102, the implement 104, and/or theattachments 130. For example, the data processing module 150 may includeinstructions that when executed by the processor 140, cause the remotecomputing device 106 to receive/access/retrieve machine data. The dataprocessing module 150 may include further instructions for storing themachine data in one or more tables of the database 180. The dataprocessing module 150 may store raw machine data, or processed data.

The data processing module 150 may include instructions for processingthe raw machine data to generate processed data. For example, theprocessed data may be data that is represented using data types data ofa programming language (e.g., R, C#, Python, JavaScript, etc.). The dataprocessing module 150 may include instructions for validating the datatypes present in the processed data. For example, the data processingmodule 150 may verify that a value is present (i.e., not null) and iswithin a particular range or of a given size/structure. In someembodiments, the data processing module 150 may transmit processed datafrom the database 180 in response to a query, or request, from theclient computing device 102. The data processing module 150 may transmitthe processed data via HTTP or via another data transfer suitableprotocol.

For example, in an embodiment, the data processing module 150 of FIG. 1may include a set of computer-executable instructions for analyzingremotely-sensed imagery (e.g., high-resolution visible and near-infrared(VNIR) imagery) to estimate plant physiological properties. The dataprocessing module 150 may include further computer-executableinstructions for analyzing the plant physiological properties to computeone or more VPI value predictions. Specifically, the data processingmodule 150 may include instructions for extracting one or morecombinations of spectral bands (e.g., one or more vegetation indices,one or more derivative spectroscopy values, etc.) from theremotely-sensed imagery, and analyze the combinations of spectral bandsto predict VPI values. In still further embodiments, the data processingmodule 150 may analyze soil data and/or topographic attributes (e.g.,soil bulk density, SWI, CEC, OM, etc.) to predict one or more VPIvalues. The data processing module 150 may analyze these predicted VPIvalues to determine one or more environment-specific varietal responses,allowing for the development of multi-genetics planting recommendations(i.e., variety changes as the planter travels across the field) asdepicted in FIG. 7 , below.

The topographic module 152 may include instructions for retrieving,accessing and/or providing mapping data (e.g., electronic map layerobjects) to other modules in the remote computing device 106. Themapping data may take the form of raw data. In some embodiments, thetopographic module 152 may include spatial data files. The topographicmodule 152 may store mapping data in, and retrieve mapping data from,the database 180. The topographic module 152 may source elevation datafrom public sources, such as the United States Geological Survey (USGS)National Elevation Dataset (NED) database. In some embodiments, the dataprocessing module 150 may provide raw data to the topographic module152, wherein instructions within the topographic module 152 infer theelevation of a particular tract of land by analyzing the raw data. Theelevation data may be stored in a two-dimensional (2D) orthree-dimensional (3D) data format, depending on the embodiment andscenario.

Exemplary Variety Profile Index (VPI) Value Determination Embodiments

The VPI determining module 154 may process machine data to predict oneor more VPI values corresponding to one or more subdivisions of anagricultural field or sub-field. In some embodiments, fields andsub-fields are divided into a grid of interlaced, hexagonal cells,called “hexagrids” herein. In some embodiments, the hexagrids are 8.5meters across. In some embodiments, the VPI determining module 154 mayprocess the machine data using a trained machine-learned (ML) model, asdescribed with respect to FIG. 3 .

Turning to FIG. 3 , a block diagram of an example VPI determining module300 is depicted. The VPI determining module 300 may correspond to theVPI determining module 154 of FIG. 1 . The VPI determining module 300may include instructions for training and operating one or more MLmodels 302 to predict one or more VPI values 304 corresponding to anagricultural field or sub-field based on input vectors of machine data305 (e.g., data collected and/or processed by the data processing module150) or values determined from the machine data 305 (e.g., an average,etc.). The ML model 302 may include a statistical model such as amultinomial logistic regression model, a decision tree, a gradientboosting model, a random forest model, a logistic regression model, etc.The predicted VPI values 304 may be associated with one or morehexagrids.

The block diagram includes a data transformer 308 that generates one ormore input data vectors 306 for the ML model 302 by transforming themachine data 305. Specifically, the data transformer 308 may includeinstructions for processing the machine data 305 to generate inputvectors 306 for the ML model 302. For example, computing averages,removing noise, unit conversions, computing a value of a first type froma value of a second type, computing a value or index based on one ormore physical measurements, etc. An example input vector 306 for the MLmodel 302 includes one or more of soil topography, relative elevation,slope, latitude, growing season length, incident solar radiation,phosphorus fertility, potassium fertility, soil wetness index (SWI),organic matter, CEC, etc.

The machine data 305 may include image data (e.g., overhead imagery,visible imagery, near-infrared imagery, etc.), as discussed with respectto FIG. 7 . When the machine data includes image data, the input vectors306 may include biomass and/or leaf area values, as determined from theoverhead imagery by the data transformer 308 and/or the data processingmodule 150. Examples of plant biomass may be values that describe agiven plant's total dry mass, dry mass or specific components/organs(i.e., leaves, stems, roots), while leaf area quantifies the area ofleaves that are actively photosynthesizing and producing carbohydrate.It should be noted by those skilled in the art that remotely sensedimagery, specifically visible-near-infrared (VNIR) imagery, is a goodpredictor of plant biomass, leaf area index and overall plant structure.The input vectors 306 may be labeled with the geographic coordinates ofa respective hexagrid corresponding to the input values and, when known,respective VPI values determined using one or more plants located in thehexagrid. For example, a field may include a plurality of hexagrids,wherein each hexagrid includes a respective plurality of soybean plants.The present techniques may include determining a respective VPI valuefor each of the soybean plants, and assigning the respective VPI valueto each respective plant.

The present techniques may determine the respective VPI value using amanual process and/or via an automated process. Specifically, one ormore humans may manually thresh each soybean plant as described above,and enter the information into a computer, associating each threshedplant's VPI value with the machine data 305. In other embodiments, animplement may generate the machine data 305, wherein the generatedmachine data 305 includes point data including respective VPI values foreach point in an agricultural field. In this way, the present techniquesmay analyze an individual field/sub-field (e.g., one or more hexagrids)to identify individual soybean plants, and the respective VPI value ofeach of the plants.

Returning to FIG. 3 , the VPI determining module 300 may train the MLmodels 302 by implementing a comparator 310. When the VPI determiningmodule 300 is training the ML models 302, the data transformer 308 maygenerate input data vectors 306 using the machine data 305 that includeknown VPI values 312 (e.g., wherein the VPI values 312 were manuallydetermined, as described above). In this way, the machine data 305 maybe said to be labeled data, and the data transformer 308 may preservesuch labels when transforming the machine data 305. Specifically, eachinput data vector 306 may include a respective label corresponding tothe VPI value of each respective input vector 306. The ML models 302 mayprocess each vector of input data 306 to learn to predict the one ormore VPI values 304.

In general, the present techniques may train the ML models 302 by, interalia, establishing a network architecture, or topology, and adding oneor more layers that may be associated with one or more respectiveactivation functions (e.g., a rectified linear unit, softmax, etc.),loss functions and/or optimization functions. Multiple different typesof artificial neural networks may be employed, including withoutlimitation, recurrent neural networks, convolutional neural networks,and deep learning neural networks. Data sets used to train theartificial neural network(s) may be divided into training, validation,and testing subsets; these subsets may be encoded in an N-dimensionaltensor, array, matrix, or other suitable data structures. Training maybe performed by iteratively training the network using labeled trainingsamples (e.g., training samples labeled using one or moreobserved/measured VPI values). Training of the artificial neural networkmay produce byproduct weights, or parameters which may be initialized torandom values. The weights may be modified as the network is iterativelytrained, by using one of several gradient descent algorithms, to reduceloss and to cause the values output by the network to converge toexpected, or “learned”, values.

In an embodiment, a regression neural network may be selected whichlacks an activation function, wherein input data may be normalized bymean centering, to determine loss and quantify the accuracy of outputs.Such normalization may use a mean squared error loss function and meanabsolute error. The artificial neural network model may be validated andcross-validated using standard techniques such as hold-out, K-fold, etc.In some embodiments, multiple artificial neural networks may beseparately trained and operated, and/or separately trained and operatedin conjunction. The ML models 302 may include instructions executed by aprocessor or a processing element using supervised or unsupervisedmachine learning, and the machine learning module may employ a neuralnetwork, which may be a convolutional neural network, a deep learningneural network, or a combined learning module or program that learns intwo or more fields or areas of interest. Machine learning may involveidentifying and recognizing patterns in existing data in order tofacilitate making predictions for subsequent data. Models may be createdbased upon example inputs in order to make valid and reliablepredictions for novel inputs. For example, a deep learning artificialneural network may be trained using historical machine data togeneralize about previously unseen machine data. The ML models 302 maystore one or more trained ML models in a memory and/or in an electronicdatabase. The ML models 302 may transmit trained ML models to anothercomponent of the computing environment 100 (e.g., the client computingdevice 102).

In particular, the comparator 310 may compute differences 314 betweenthe known VPI values 312 and the corresponding predicted VPI values 304,and the ML model 302 updates one or more of its parameters (e.g.,coefficients, weights, etc.) based upon the VPI values 312 using, forexample, predictive modeling. The comparator 310 may process may berepeated until a statistical measure (e.g., root mean square (rms),least squares, quadratic loss, etc.) of the differences 314 satisfies apredetermined threshold. The comparator 310 may use a gradient descentoptimization algorithm to minimize the differences 314.

In operation, the VPI determining module 300 may be used to infer one ormore VPI values of machine data for a field that was not used to trainthe VPI determining module 300. That is, the VPI determining module 300may train the one or more ML models 302 using labeled data as describedabove. Next, machine data 305 corresponding to an agricultural field maybe collected (e.g., using the implement 104 of FIG. 1 ). The machinedata 305 may be transformed by the data transformer 308 to generateinput vectors 306. The trained ML models 302 may process the inputvectors 306 to determine one or more respective predicted VPI values304.

Returning to FIG. 1 , the prescription module 156 includescomputer-executable instructions for generating one or more agriculturalprescriptions. The agricultural prescriptions may be a set ofcomputer-executable instructions for performing one or more agriculturalinterventions with respect to an agricultural field. For example, theagricultural prescription may include one more map layers specifying arespective set of interventions relating to seeding, fertilization,tillage, etc. The client computing device 102 may receive/retrieve theprescription instructions, and execute them.

The prescription module 156 may include generating one or moreagricultural prescriptions, or scripts. The agricultural prescriptionsmay include computer-executable instructions for causing an implement(e.g., the implement 104) to perform one or more tasks (e.g., instruct aplanter to switch from product A to product B). In some embodiments, theprescription may include instructions for performing the tasks inresponse to a clay type at a location within a given field. For example,the implement control module 120 may analyze a field map layer receivedfrom the topographic module 152 and a clay map layer. The implementcontrol module 120 may execute the prescription. The prescription mayinclude instructions causing the implement 104 to perform the task in apredetermined way (e.g., plant seeds at a specific rate) when 1) thelocation of the implement 104 coincides with a minimum VPI value; and 2)the location of the implement 104 coincides with a particular field, asdetermined by reference to the field map layer. In this way, theprescription module 156 may generate prescriptions executable by aclient device for modifying a soil to include, for example, more of agiven macronutrient (e.g., potassium).

The prescription module 156 may be generated by a suitable tool. Forexample, in some embodiments, the remote computing device 106 mayinclude a further module that allows the user to specify the number ofyears desired to build soil potassium to a critical/target level. Theprescription module 156 may include instructions for calculating, basedon the target rate and the current rate as seen in the machine data, anamount of macronutrient to apply to cause the soil to reach the targetvalue.

The remote computing device 106 may further include one or moredatabases 180, one or more input devices 182, and one or more outputdevices 184. The database 180 may be implemented as a relationaldatabase management system (RDBMS) in some embodiments. For example, thedatabase 180 may include one or more structured query language (SQL)databases, a NoSQL database, a flat file storage system, or any othersuitable data storage system/configuration. In general, the database 180allows the client computing device 102 and/or the remote computingdevice 106 to create, retrieve, update, and/or retrieve records relatingto performance of the techniques herein. For example, the database 180may allow the client computing device 102 to store information receivedfrom one or more sensors of the implement 104 and/or the attachments130. The database 180 may include a Lightweight Directory AccessProtocol (LDAP) directory, in some embodiments. The client computingdevice 102 may include a module (not depicted) including a set ofinstructions for querying an RDBMS, an LDAP server, etc. For example,the client computing device 102 may include a set of database driversfor accessing the database 180 of the remote computing device 106. Insome embodiments, the database 180 may be located remotely from theremote computing device 106, in which case the remote computing device106 may access the database 180 via the NIC 114 and the network 108.

The input device(s) 182 may include any suitable device or devices forreceiving input, such as one or more microphones, one or more cameras, ahardware keyboard, a hardware mouse, a capacitive touch screen, etc. Theinput device(s) 182 may allow a user (e.g., a system administrator) toenter commands and/or input into the remote computing device 106, and toview the result of any such commands/input in the output device(s) 184.For example, an employee of the agrilytics company may use the inputdevice 182 to adjust parameters with respect to one or more agriculturalfields for applying macronutrients via a prescription.

The output device(s) 184 may include any suitable device for conveyingoutput, such as a hardware speaker, a computer monitor, a touch screen,etc. The remote computing device 106 may be associated with (e.g.,leased, owned, and/or operated by) an agrilytics company. As notedabove, the remote computing device 106 may be implemented using one ormore virtualization and/or cloud computing services. One or moreapplication programming interfaces (APIs) may be accessible by theremote computing device 106.

In operation, the agrilytics company may access the remote computingdevice 106 to establish one or more field records on behalf of one ormore growers. For example, the company may store the field records inthe database, wherein each grower is associated with a unique identifier(e.g., a universally unique identifier (UUID)) as are each of thegrower's respective fields. For example, the grower may be associatedwith the grower's fields in the database via a one-to-many relationship.

The agrilytics company may populate the database 180 with machine datacorresponding to the grower's fields by using the implement 104 to drivethe fields and collect the machine data. The machine data may includeinformation gathered from an attachment 130 (e.g., a soil probe) and/ormachine data collected from other sources. The agrilytics company mayadditionally populate the database 180 with VPI values corresponding tothe grower's fields by sampling and threshing soybean plants, asdescribed above. Once the machine data and VPI values for the grower'sfields have been collected, the VPI determining module 154 may processthe machine data to determine predicted VPI values. The VPI values maybe assigned to one or more hexagrids within the field.

The prescription module 156 may include instructions that analyze theVPI values of the field and determine one or more treatments foraffecting portions of the field. For example, the prescription module156 may be pre-programmed to switch soybean varieties when specificenvironmental characteristics (i.e., soil, topography) change within ahexagrid or combination of hexagrids. The instructions for switchingsoybean varieties may vary based on the predicted VPI values of thehexagrid. It should be appreciated that the examples provided areintentionally simplified for explanation, and many further embodimentsare envisioned, as described below.

Exemplary Computer-Implemented Methods

FIG. 4 depicts a flow diagram of an example computer-implemented method400 for training a ML model to predict one or more VPI values within anagricultural field, according to one embodiment. The method 400 may beimplemented as an executable program or portion of an executable programfor execution by a processor such as the processor 110, 140 of FIG. 1 .The program may be embodied in software and/or machine-readableinstructions stored on a non-transitory, machine-readable storage mediumsuch as a compact disc (CD), hard disk drive (HDD), digital versatiledisk (DVD), Blu-ray disk, cache, flash memory, read-only memory (ROM),random access memory (RAM), or any other storage device or storage diskassociated with the processor 110, 140 in which information may bestored for any duration (e.g., for extended time periods, permanently,for brief instances, for temporarily buffering, and/or for caching ofthe information). The order of execution of the blocks of FIG. 4 may bechanged, and/or some of the blocks described may be changed, eliminated,or combined. Additionally, or alternatively, any or all of the blocksmay be implemented by one or more of a hardware circuit (e.g., discreteand/or integrated analog and/or digital circuitry), application specificintegrated circuit (ASIC), programmable logic device (PLD), fieldprogrammable gate array (FPGA), field programmable logic device (FPLD),logic circuit, etc. structured to perform the corresponding operation(s)without executing software or instructions.

The method 400 may include accessing a machine data set corresponding tothe agricultural field (block 402). The machine data set may includelabeled data corresponding to the agricultural field (e.g., one or moremeasurements taken using a soil probe corresponding to soil values). Thesoil probe may include manual, hydraulic and/or electronic aspects, insome embodiments and scenarios. Specifically, the implement 104 maycollect machine data using the soil probe. In some embodiments, thecollected machine data set may include historical machine data collectedpreviously. The historical machine data may be collected by theimplement 104 or another process/actor, in some embodiments. The machinedata may include data collected from multiple mechanisms (e.g., fromfarm equipment, from one or more soil probes, and/or other sources). Themethod 400 may include accessing known VPI values corresponding to theagricultural field (block 404). For example, the method 400 may access arespective VPI value for each of a plurality of soil samples.

In some embodiments, the method 400 may include labeling the machinedata with the known VPI values (block 406). The method 400 may includeprocessing the labeled machine data with the ML model 302 to train oneor more ML models to generate predicted VPI values corresponding to theknown VPI values (block 408). The method 400 may include computingdifferences between the known VPI values and the predicted VPI values(block 410). The method 400 may include updating one or more parameters(e.g., coefficients, weights, etc.) of the ML model 302 based upon thedifferences (block 412). The method 400 may include repeating blocks408-412 until a statistical measure (e.g., rms, least squares, etc.) ofthe differences 314 satisfies a predetermined threshold. The method 400may include storing the trained ML models and/or the weights/parametersof each of the respective trained ML models in a non-transitory memoryand/or an electronic database for later use (e.g., to predict one ormore VPI values corresponding to an agricultural field, an agriculturalsub-field, a hexagrid, etc.).

FIG. 5 depicts a flow diagram of an example computer-implemented method500 for improving agricultural treatment application within anagricultural field, according to one embodiment and scenario. The method500 may be implemented using an executable program or portion of anexecutable program for execution by a processor such as the processor110, 140 of FIG. 1 . The program may be embodied in software and/ormachine-readable instructions stored on a non-transitory,machine-readable storage medium such as a CD, HDD, DVD, Blu-ray disk,cache, flash memory, ROM, RAM, or any other storage device or storagedisk associated with the processor 110, 140 in which information may bestored for any duration (e.g., for extended time periods, permanently,for brief instances, for temporarily buffering, and/or for caching ofthe information). The order of execution of the blocks of FIG. 5 may bechanged, and/or some of the blocks described may be changed, eliminated,or combined. Additionally, or alternatively, any or all of the blocksmay be implemented by one or more of a hardware circuit (e.g., discreteand/or integrated analog and/or digital circuitry), ASIC, PLD, FPGA,FPLD, logic circuit, etc. structured to perform the correspondingoperation(s) without executing software or instructions.

The method 500 may include collecting a machine data set correspondingto the agricultural field (block 502). The machine data setcorresponding to the agricultural field may include one or moremeasurements taken using a soil probe. The soil probe may includemanual, hydraulic and/or electronic aspects, in some embodiments andscenarios. Specifically, an implement (e.g., the implement 104 of FIG. 1) may collect a plurality of measurements corresponding to data pointswithin the agricultural field using the soil probe. The implement 104may transmit the collected measurements as machine data to the remotecomputing device 106 of FIG. 1 , as described herein. In someembodiments, the collected machine data set may include historicalmachine data collected previously. The historical machine data may becollected by the implement 104 or another process/actor, in someembodiments. The machine data may include data collected from multiplemechanisms (e.g., from farm equipment, from one or more soil probes,and/or other sources).

The method 500 may include analyzing the machine data set with the oneor more trained ML models 302 to predict one or more VPI valuescorresponding to one or more respective hexagrids located within theagricultural field (block 504). As noted above, the collection andanalysis of machine data may be performed by the client computing device102 and/or the remote computing device 106. In either case, the method500 may annotate each data point within the machine data with ageographic position. The geographic position of each point may be addedto the machine data upon collection by an implement and/or a computingdevice (e.g., by an onboard Global Positioning System (GPS) device ofthe implement 104 or the client computing device 106).

The method 500 may associate each hexagrid with the determined VPIvalues, such that once the method 500 has been completed, each of thehexagrids within the field includes one or more respective VPI valuescorresponding to the individual soybean plants and/or varieties locatedwithin that hexagrid. In this way, the grower, field manager, trustedadvisor or other relevant party can advantageously gain an objectiveunderstanding of how different regions of the field are influencing VPI(e.g., by viewing a field map layer showing respective VPI values forthe field). The ability to view differing VPI values is advantageous forpractical growing purposes. For example, a grower operating theimplement 104 of FIG. 1 may view the field map layer including VPIvalues and initiate prescriptive fungicide applications in areas wheresoybean plants are more likely to have additional growth (e.g., havehigher VPI values) in connection with a higher yield environment.

As discussed above, the method 500 may include generating andtransmitting (e.g., from the remote computing device 106) one or moremap layers via the network 108 for display in the client computingdevice 106. The one or more map layers may include the predicted VPIvalues, in some embodiments. In still further embodiments, the presenttechniques may be used, optionally in conjunction with other non-VPIcharacteristics map layers, to automate the application of agriculturaltreatments. For example, the method 500 may include generating anagricultural prescription for the agricultural field, including at leastone treatment based on the VPI values (block 506). An exampleprescription includes variety selection, seeding rate, field plantingpriority, in season management including fertility (e.g., macro ormicronutrients spread or foliar sprayed), crop protection (e.g.,fungicide, insecticide), biologicals, etc.

However, the present techniques represent a further advantageousimprovement over conventional techniques that require the grower tomaintain constant attention during the laborious planting and harvestseasons, which may be further challenging due to hot/cold weather,precipitation and, in many cases, working in darkness. To that end, themethod 500 may include performing the generated agriculturalprescription by, for example, transmitting the prescription in the formof an electronic prescription file to the client computing device 102for execution in the implement control module 120 (block 508). Theagricultural prescription may include sets of instructions forautomatically applying a treatment in portions of the field thatcorrespond with certain VPI values.

The agricultural prescription may access a location module (e.g., a GPSmodule) of the client computing device 102 to determine the real-timeposition of the implement within the field, with respect to the fieldmap layer associated with VPI values information. The agriculturalprescription may include instructions for causing a pre-determinedagricultural treatment to be applied to the field, for example byaccessing an attachment (e.g., the attachment 130 of FIG. 1 ). In thisway, the present techniques may be advantageously used to identify VPIvalues corresponding a field, which may be highly variable for thereasons discussed above. The present techniques may furtheradvantageously be used to automatically apply treatment product based onthe VPI values, to conserve product while increasing yields.

Exemplary Variety Profile Index (VPI) Visualization Embodiments

In still further embodiments, the predicted VPI values for the field maybe analyzed to generate one or more visualizations for comparing thepotential effects of applying various agricultural products to theagricultural field. Specifically, in some embodiments, the dataprocessing module 150 of FIG. 1 may include instructions for generatingone or more visualizations (e.g., a chart, a graphic, a webpage, etc.)depicting the predicted VPI values generated by the trained ML models ofthe VPI determining module 154.

FIG. 6A depicts an example chart 602 for visualizing yield performanceamong products having differing variety profile indices, according to anembodiment. The chart 602 includes a horizontal axis depicting aplurality of different agricultural varieties (e.g., soybean seeds). Thevertical axis depicts a measure of each variety's computed VPI. Thevalues for each variety are plotted in the chart, enabling the grower,field manager, etc. to intuitively and advantageously grasp, at aglance, each variety's respective ability to benefit from a higher yieldenvironment. In particular, those varieties having a higher VPI are morelikely to benefit from a high yield environment, whereas those with alower VPI are not. The ability to compute and visualize VPI values inthis manner, with respect to different varieties, advantageously enableskey decision-makers to reference objective data when making productrecommendations.

FIG. 6B depicts an example chart 604 for visualizing average varietyprofile indices across products among different fields, according to anembodiment. In particular, the chart 604 depicts the respectiveperformance of five varieties in four separate fields. The chart 604advantageously enables the grower, field manager, etc. to intuitivelyand advantageously grasp, at a glance, each variety's respectiveperformance among different fields, and to determine the extent to whichVPI is consistent across varying locations. Based on the information inthe chart 604, the trusted advisor, for example, may recommend plantingof a variety, such as Variety 1, that consistently performs at or abovea baseline VPI of 0.4. Of course, the chart 604 is intentionallysimplified for explanation, and may include other/less data; fewer/morefields; and/or different ranges of VPI values, in some embodiments andscenarios.

FIG. 6C depicts an example chart 606 for visualizing soil wetness index(SWI) data compared to average yield among different products, accordingto an embodiment. The chart 606 is an example of a chart that a trustedadvisor, for example, may provide to a customer in conjunction withinformation related to VPI values for certain products. Specifically,the chart 606 includes a top horizontal axis specifying a plurality ofagricultural varieties. The chart 606 includes a vertical axis depictingthe change in SWI yield as compared to an average. For each product, thechange in yield is plotted for low, medium and high SWI. The chart 606enables the trusted advisor, for example, to communicate the effect ofSWI on yield across different products. In some embodiments, the data inthe chart 606 may be combined/cross-referenced with data, such that fora given product, a composite value of SWI information and VPI values areprovided for a given agricultural product. In some embodiments, thepresent techniques may base an agricultural prescription and/or a fieldmanagement recommendation on this composite value.

FIG. 6D depicts an example chart 608 for visualizing a respectiveaverage variety profile index for a plurality of agricultural varieties,according to an embodiment. The chart 608 enables the grower to rapidlydetermine the suitability of each variety. For example, the viewer maydetermine that a VPI value of greater than 0.4 indicates performance inhigher yielding environment as with Variety 6. The viewer may determinethat a VPI value of below 0.4 requires specific variety placement as inthe example of Variety 7. The viewer may determine that Variety 8, at aVPI value of 0.2, is a better fit for a stress environment, and willlikely respond with higher yields given an increase in plant population.

FIG. 6E depicts an example chart 610 for visualizing yields according toplant population among a plurality of agricultural varieties, accordingto an embodiment. The chart 610 includes a top horizontal axis depictinga plurality of respective plant population, and for each plantpopulation, a bottom horizontal axis listing a plurality of agriculturalproducts. The VPI of each product is depicted in the chart 610. Byviewing the chart 610, the trusted advisor, grower, customer, etc. isadvantageously able to determine, instantly and intuitively, therespective performance of products given different populationconditions. For example, the viewer can quickly determine that lower VPIproducts generally have a stronger response to population, and thatincreasing population may lead to an increase or a decrease in yield,depending on which variety is selected.

In general, the charts 6A-6E advantageously provide decision-makers inall areas of precision agriculture with the tools to quantifyinformation related to variety performance among different fields,different environments. The visualization techniques herein enable fastand easy visualization and communication of quantified information toother parties, thus improving field management computing systems. Forexample, the field advisor need not base product recommendations to afield owner with an intuition, an anecdote or a best guess regardingvariety performance.

FIG. 7 depicts an exemplary multi-genetics prescription map 700,according to an embodiment. The map 700 includes a first product coding702 and a second product coding 704. The first product coding 702 andthe second product coding 704 are depicted within respective cells of amap layer 706. The cells of the map layer 706 may be color-coded usingthe first product coding 702 and the second product coding 704 toindicate cells wherein the respective product will be applied. Forexample, the product coding 702 and the product coding 704 may be tworespective soybean varieties determined using the techniques describedherein. The topographic module 152 of FIG. 1 may generate the map layer706 to include a plurality of predicted VPI values each corresponding toa respective field subdivision (e.g., a respective hexagrid) of the maplayer 706. In some embodiments, the map layer 706 may be used as avisual tool prior to and/or during the planting process.

Additional Considerations

The following considerations also apply to the foregoing discussion.Throughout this specification, plural instances may implement operationsor structures described as a single instance. Although individualoperations of one or more methods are illustrated and described asseparate operations, one or more of the individual operations may beperformed concurrently, and nothing requires that the operations beperformed in the order illustrated. These and other variations,modifications, additions, and improvements fall within the scope of thesubject matter herein.

It should also be understood that, unless a term is expressly defined inthis patent using the sentence “As used herein, the term” “is herebydefined to mean . . . ” or a similar sentence, there is no intent tolimit the meaning of that term, either expressly or by implication,beyond its plain or ordinary meaning, and such term should not beinterpreted to be limited in scope based on any statement made in anysection of this patent (other than the language of the claims). To theextent that any term recited in the claims at the end of this patent isreferred to in this patent in a manner consistent with a single meaning,that is done for sake of clarity only so as to not confuse the reader,and it is not intended that such claim term be limited, by implicationor otherwise, to that single meaning.

Unless a claim element is defined by reciting the word “means” and afunction without the recital of any structure, it is not intended thatthe scope of any claim element be interpreted based on the applicationof 35 U.S.C. § 112(f).

Unless specifically stated otherwise, discussions herein using wordssuch as “processing,” “computing,” “calculating,” “determining,”“presenting,” “displaying,” or the like may refer to actions orprocesses of a machine (e.g., a computer) that manipulates or transformsdata represented as physical (e.g., electronic, magnetic, or optical)quantities within one or more memories (e.g., volatile memory,non-volatile memory, or a combination thereof), registers, or othermachine components that receive, store, transmit, or displayinformation.

As used herein any reference to “one embodiment” or “an embodiment”means that a particular element, feature, structure, or characteristicdescribed in connection with the embodiment is included in at least oneembodiment. The appearances of the phrase “in one embodiment” in variousplaces in the specification are not necessarily all referring to thesame embodiment.

As used herein, the terms “comprises,” “comprising,” “includes,”“including,” “has,” “having” or any other variation thereof, areintended to cover a non-exclusive inclusion. For example, a process,method, article, or apparatus that comprises a list of elements is notnecessarily limited to only those elements but may include otherelements not expressly listed or inherent to such process, method,article, or apparatus. Further, unless expressly stated to the contrary,“or” refers to an inclusive or and not to an exclusive or. For example,a condition A or B is satisfied by any one of the following: A is true(or present) and B is false (or not present), A is false (or notpresent) and B is true (or present), and both A and B are true (orpresent). As used herein, the phrase “at least one of A and B” isintended to refer to any combination or subset of A and B such as (1) atleast one A, (2) at least one B, and (3) at least one A and at least oneB. Similarly, the phrase “at least one of A or B” is intended to referto any combination or subset of A and B such as (1) at least one A, (2)at least one B, and (3) at least one A and at least one B.

In addition, use of “a” or “an” is employed to describe elements andcomponents of the embodiments herein. This is done merely forconvenience and to give a general sense of the invention. Thisdescription should be read to include one or at least one and thesingular also includes the plural unless it is obvious that it is meantotherwise.

Further, as used herein, the expressions “in communication,” “coupled”and “connected,” including variations thereof, encompasses directcommunication and/or indirect communication through one or moreintermediary components, and does not require direct mechanical orphysical (e.g., wired) communication and/or constant communication, butrather additionally includes selective communication at periodicintervals, scheduled intervals, aperiodic intervals, and/or one-timeevents. The embodiments are not limited in this context.

Upon reading this disclosure, those of ordinary skill in the art willappreciate still additional alternative structural and functionaldesigns for implementing the concepts disclosed herein, through theprinciples disclosed herein. Thus, while particular embodiments andapplications have been illustrated and described, it is to be understoodthat the disclosed embodiments are not limited to the preciseconstruction and components disclosed herein. Various modifications,changes and variations, which will be apparent to those of ordinaryskill in the art, may be made in the arrangement, operation and detailsof the method and apparatus disclosed herein without departing from thespirit and scope defined in the appended claims.

What is claimed:
 1. A computing system for characterizing soybean plantsusing machine learning, the computing system comprising: one or moreprocessors; and one or more non-transitory, computer-readable mediaincluding instructions that, when executed by the one or moreprocessors, cause the computing system to: receive a machine data setcorresponding to an agricultural field; process the machine data setwith a trained machine-learned model to generate one or more predictedvariety profile index values, the trained machine-learned model trainedusing labeled data including a ratio of at least one measured branchbean weight to at least one measured stem bean weight; and transmit, viaan electronic network, the one or more predicted variety profile indexvalues to a client computing device.
 2. The computing system of claim 1,wherein the labeled data is determined using a lower portion of asoybean plant.
 3. The computing system of claim 2, wherein the portionof the soybean plant includes a first above-ground node to a fifteenthabove-ground node of the soybean plant.
 4. The computing system of claim1, wherein a variety profile index value characterizes a plant typehaving a determined bushiness.
 5. The computing system of claim 1,wherein the labeled data includes one or more measurements taken using asoil probe.
 6. The computing system of claim 1, wherein the machine dataset includes topographic data.
 7. The computing system of claim 1,wherein the machine data set includes one or more images taken of theagricultural field.
 8. The computing system of claim 1, wherein themachine data set includes one or both of 1) biomass, and 2) leaf areavalues determined from one or more images taken of the agriculturalfield.
 9. A computer-implemented method for training a machine learningmodel to characterize soybean plants, the method comprising: receiving amachine data set corresponding to an agricultural field; processing themachine data set with a trained machine-learned model to generate one ormore predicted variety profile index values, the trained machine-learnedmodel trained using labeled data including a ratio of at least onemeasured branch bean weight to at least one measured stem bean weight;and transmitting, via an electronic network, the one or more predictedvariety profile index values to a client computing device.
 10. Themethod of claim 9, wherein the labeled data is determined using a lowerportion of a soybean plant.
 11. The method of claim 10, wherein theportion of the soybean plant includes a first above-ground node to afifteenth above-ground node of the soybean plant.
 12. The method ofclaim 9, wherein a variety profile index value characterizes a planttype having a determined bushiness.
 13. A non-transitorycomputer-readable medium, having instructions stored thereon that, whenexecuted by one or more processors, cause a computer to: receive amachine data set corresponding to an agricultural field; process themachine data set with a trained machine-learned model to generate one ormore predicted variety profile index values, the trained machine-learnedmodel trained using labeled data including a ratio of at least onemeasured branch bean weight to at least one measured stem bean weight;and transmit, via an electronic network, the one or more predictedvariety profile index values to a client computing device.
 14. Thenon-transitory computer-readable medium of claim 13, wherein the labeleddata is determined using a lower portion of a soybean plant.
 15. Thenon-transitory computer-readable medium of claim 14, wherein the portionof the soybean plant includes a first above-ground node to a fifteenthabove-ground node of the soybean plant.
 16. The non-transitorycomputer-readable medium of claim 13, having stored thereon furtherinstructions that, when executed by one or more processors, cause acomputer to: generate an agricultural prescription for a secondagricultural field based on the predicted variety profile index values.17. The non-transitory computer-readable medium of claim 13, wherein themachine data set includes one or more measurements taken using a soilprobe.
 18. The non-transitory computer-readable medium of claim 13,wherein the machine data set includes one or more images taken of afirst agricultural field.
 19. The non-transitory computer-readablemedium of claim 13, wherein the machine data set includes one or both ofbiomass or leaf area values determined from one or more images taken ofa first agricultural field.
 20. The non-transitory computer-readablemedium of claim 13, having stored thereon further instructions that,when executed by one or more processors, cause a computer to: display,in a client computing device, a variety profile index map layer in agraphical user interface, the variety profile index map layer depictingthe one or more predicted variety profile index values within a secondagricultural field.